KR101535811B1 - Antena interface device for mobile communication radioaccess system - Google Patents

Abstract

The present invention relates to an antenna interface device of a mobile communication base station. The antenna interface device comprises: a lower interface unit (200) connected to communication wires (110) of a base station device unit (100), transmitting transmission signals of the communication wires (110) through one RF cable (120), transmitting a control signal and DC power through the RF cable (120), receiving a combined signal of signals received by antennas (400) through the RF cable (120), and branching and provide the same to the communication wires (110); an upper interface unit (300) for receiving a transmission signal of the base station device unit (100) through the RF cable (120), branching the same to a transmission signal of each of the communication wires (110) to be transmitted to each of the antennas (400), transmitting a control signal and DC power to RET (410) installed in each of the antennas (400), and combining the signals received through the antennas (400) to be transmitted to the lower interface unit (220) through the RF cable (120); and an AISG controller (500) for controlling the RET (410) by communicating with the lower interface unit (200) through an RS485 technique or an OOK technique.

Description

[0001] The present invention relates to an antenna interface device for a mobile communication base station,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna interface apparatus of a mobile communication base station, and more particularly, to an antenna interface apparatus of a mobile communication base station that conforms to the AISG 3.0 standard and can reduce the number of lines.

Generally, an antenna used in a mobile communication base station includes a function that can be remotely controlled. For example, the tilt angle of the antenna can be adjusted by remote electrical tilt (RET), and the controller can perform the control function of the tower mounted amplifier (TMA: Tower Mounted Amplifier).

The above control is performed through the AISG master controller, and the communication between the AISG master controller and RET, TMA, and CBT (Conversion Bias Tee) complies with the RS485 standard. In addition, the OOK method is also used. .

The RS485 method is a basic communication interface of an antenna line device (ALD), but a multi core cable should be used for the AISG master communication. Depending on the installation conditions between the AISG master and the ALD, There is a problem that it is difficult to install a plurality of long cables.

In particular, since different carriers use different frequencies, it is necessary to divide RF signals of various frequencies into separate pieces of equipment and connect them to equipment such as an antenna. Even if the same frequency is used, the antenna needs at least three And communication cable, power cable and RF cable should be connected according to the number.

1 is a block diagram of an embodiment of an antenna system of a conventional mobile communication base station.

Referring to FIG. 1, an antenna system of a conventional mobile communication base station includes a plurality of antennas 2 to which a base station unit (BTS) 1 and an RF cable (RF) capable of transmitting and receiving RF signals are connected, 2 for controlling the tilt angle of the antenna 2 through communication with the AISG controller 3.

The RET 4 communicates with the AISG controller 3 through the RS485 method and changes the tilt angle of the antenna 2 under the control of the AISG 3 if necessary. In such a configuration, the AISG controller 3 and the RET 4 provided on the antenna 2 may have a considerable distance difference depending on the installation environment, and a multi-core cable of the same number as the number of RETs 4 must be used, The length of the multi-core cable must be considerably long, so that a large installation cost is required and the operation is not easy.

In addition, since a separate RF cable (RF) must be connected to each of the base station apparatus unit 1 and the antennas 2 in order to transmit and receive an RF signal, the installation cost is increased and the operation is not easy.

2 is a block diagram of an antenna system of a conventional mobile communication base station using CBT.

Referring to FIG. 2, a pair of CBTs 5 and 6 are added to the upper and lower portions of the RF cable RF in the embodiment described above with reference to FIG. 1 to perform communication between the AISG controller 3 and the RET 4 And the length of the multicore cable for supplying DC power is reduced.

The CBT 5 is installed close to the base station apparatus 1 and communicates with the AISG controller 3 through the RS485 method and the CBT 6 is installed close to the antenna 2 and connected to the RET 4 RS485 communication is performed.

At this time, the communication method between the two CBTs 5 and 6 uses the OOK method using an RF cable (RF).

Therefore, the two CBTs 5 and 6 serve to relay the communication between the AISG controller 3 and the RET 4 and can use the RF cable RF directly as a communication line. Thus, the AISG controller 3 and the RET The length of the multi-core cable for communication between the base stations 4 can be reduced.

3 is a block diagram of a conventional mobile communication base station antenna system to which TMA is applied.

3, the TMA 7 is positioned close to the antenna 2 and communicates with the RET 4 in the RS485 manner. The CBT 5 and the OOK 5, which are located near the base station unit 1, And the CBT 5 communicates with the AISG controller 3 in an RS485 manner.

In this configuration as well, the TMA 7 and the CBT 5 relay the communication between the AISG controller 3 and the RET 4, and the AISG controller 3 and the RET 4, The length of the multi-core cable for communication between the terminals can be reduced.

However, in the conventional configuration shown in FIGS. 2 and 3, since the base station apparatus 1 and the plurality of antennas must be connected to each other through an RF cable, it is difficult to connect a long and heavy RF cable, The problem still remains.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems and provides a mobile communication base station antenna interface device which can comply with the AISG 3.0 standard and can integrate RF cables connecting the base station unit and the plurality of antennas into one have.

In order to solve the above-mentioned problems, the mobile communication base station antenna interface apparatus of the present invention is configured such that the communication lines 110 of the base station apparatus 100 are connected, and the transmission signals of the respective communication lines 110 are combined to form one RF cable 120, a control signal and a DC power source are transmitted through the RF cable 120, and a combined signal of signals received by the antennas 400 is received through the RF cable 120 A lower interface unit 200 for branching the RF signals to the communication line 110 and supplying RF signals to the communication line 110 through the RF cable 120, And transmits the control signal and the DC power to the RETs 410 provided for the respective antennas 400. The signals received through the antennas 400 are transmitted to the antennas 400, And the RF cable 120 And an AISG controller 500 for controlling the RET 410 by communicating with the lower interface unit 200 through an RS 485 or OOK method, do.

The mobile communication base station antenna interface apparatus of the present invention integrates transmission signals of a base station apparatus unit, transmits the signals using a single RF cable to a plurality of antennas, branches the transmission signals transmitted through the RF cable, The reception signal can be reversely processed, and the number of RF cables can be reduced, thereby facilitating the installation and reducing the cost.

Further, the present invention can transmit a control signal for controlling the RET through the RF cable, thereby reducing costs and facilitating installation and maintenance.

1 is a block diagram of an embodiment of an antenna system of a conventional base station.
2 is a block diagram of another embodiment of a conventional base station antenna system.
3 is a block diagram of another embodiment of a conventional base station antenna system.
4 is a block diagram of a mobile communication base station antenna interface apparatus according to a preferred embodiment of the present invention.
5 is a detailed configuration diagram of the lower interface unit in FIG.
6 is a detailed configuration diagram of the upper interface unit in FIG.

Hereinafter, a mobile communication base station antenna interface device according to the present invention will be described with reference to the accompanying drawings.

4 is a block diagram of a mobile communication base station antenna interface apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 4, the communication interface 110 of the base station apparatus 100 is connected to the mobile communication base station antenna interface apparatus according to the preferred embodiment of the present invention, And transmits a control signal and DC power through the RF cable 120 and a combined signal of signals received by the antennas 400 to the RF cable 120 through the RF cable 120. [ A lower interface unit 200 for receiving the transmission signal from the base station apparatus 100 and for supplying the branched signal to the communication line 110 and receiving the transmission signal of the base station apparatus 100 through the RF cable 120, And transmits the control signal and the DC power to the RET 410 provided for each of the antennas 400. The control signal and the DC power are transmitted to the antennas 400 through the antennas 400, And combines the received signals to generate RF k And an AISG controller 500 for controlling the RET 410 by communicating with the lower interface unit 200 in an RS485 manner to the lower interface unit 200 .

Hereinafter, the configuration and operation of the mobile communication base station antenna interface device according to the preferred embodiment of the present invention will be described in detail. For convenience of explanation, transmission and reception are separately described.

Also, in order to unify the terms used, the communication signal can be understood as the same concept as the RF signal, and the communication signal can be divided into the transmission signal and the reception signal. The OOK or RS485 communication is for the transmission of control signals and can be understood as the same concept as the control signals.

First, when transmitting a signal from the base station apparatus 100, a transmission signal is transmitted through a plurality of communication lines 110. The communication line 110 is an RF cable capable of substantially transmitting and receiving an RF signal.

The communication line 110 is connected to the lower interface unit 200 and the transmission signal of the communication line 110 is transmitted from the lower interface unit 200 through one RF cable 120, And merged into a transmission signal. The antennas 400 have different transmission and reception frequencies, and can transmit transmission signals having different frequencies through one RF cable 120.

The lower interface unit 200 is provided with a means for communicating with the AISG controller 500 through the RS485 method and transmits a control signal of the AISG controller 500 to the RET 410 provided for each antenna 400, The state of the RET 410 may be transmitted to the AISG controller 500. At this time, the lower interface unit 200 and the upper interface unit 300 communicate with each other through the RF cable 120 in an OOK manner, and the OOK modem is included to enable OOK communication.

And a switching means for selectively transmitting the DC power.

5 is a detailed block diagram of the lower interface unit 200. As shown in FIG.

5, the lower interface unit 200 includes a plurality of connection terminals P11 to P14 to which the communication lines 110 are connected, and an RF signal and DC power provided to the connection terminals P11 to P14 A common terminal COM1 for transmitting the transmission signals of the signal lines L11 to L14 to the connected RF cable 120 and transmitting the reception signals to the signal lines L11 to L14, Filters F11 to F14 provided in each of the signal lines L11 to L14 to divide the signals into which a plurality of communication signals are combined and transmit the signals to the signal lines L11 to L14, A power selection unit 210 for supplying a DC current selectively to the common terminal COM1 branched from the AISG controller 500 and an RS485 terminal unit 220 connected to the AISG controller 500. The AISG controller 500 and the RS485 The RS 485 driver 230 for enabling communication with the AISG controller 500 and the control of the AISG controller 500 received through the RS485 driver 230 A main modem 240 for converting a call into an OOK communication signal and transmitting the communication signal via the common terminal COM1 through the RF cable 120 and a control unit 250 for controlling the operations of the respective units .

The lower interface unit 200 may be a modem unit including a plurality of OOK modems. The lower interface unit 200 is not used in the lower interface unit 200, So that it can be used regardless of its position so as to improve the convenience of use.

That is, since the functions of the lower interface unit 200 and the upper interface unit 300 are determined according to the connection state of the ports in the same circuit configuration, it is possible to prevent the operator from changing the lower and upper portions by mistake It can be prevented in advance.

6 is a detailed block diagram of the upper interface unit 300. Referring to FIG.

6, a common terminal COM2 to which the RF cable 120 is connected, a plurality of terminal portions P21 to P24 to which the antenna 400 is connected, a main modem 340, signal lines L21 to L24, A power selection unit 310, an RS485 terminal unit 320, an RS485 driver 330, and a modem unit 360. The filters F21 to F24,

A detailed operation of the lower interface unit 200 and the upper interface unit 300 will be described with reference to the communication process of the communication line 110 input through the terminal units P11 to P14 of the lower interface unit 200, Signals are transmitted to the common terminal COM1 along the signal lines L11 to L14 and transmitted to the common terminal COM2 of the upper interface unit 300 through the RF cable 120. [ That is, a plurality of transmission signals having different frequencies can be merged and transmitted through one RF cable 120, thereby facilitating the installation of the RF cable and reducing the cost.

The power supply selection unit 210 of the lower interface unit 200 selectively supplies DC power supplied through the terminal units P11 to P14 to the modem unit 260, the main modem 240, and the RS 485 terminal unit 220 And supplies the DC power to the upper interface unit 300 through the common terminal COM1 and the RF cable 120. [

When the control signal of the AISG controller 500 is inputted through the RS 485 terminal unit 220, the control signal is converted into the OOK system through the main modem 240 and is transmitted to the common terminal COM1 and the RF cable 120 together with the DC power. To the upper interface unit 300.

Through this process, the RF signal, the DC power, and the control signal of the OOK communication method can be transmitted together through one RF cable.

The communication signal, the DC power supply, and the control signal of the lower interface unit 200 are transmitted to the common terminal COM2 of the upper interface unit 300 through the RF cable 120. [ The communication signal transmitted to the common terminal COM2 is filtered through only the transmission signals having frequencies corresponding to the respective antennas 400 through the filter units F21 to 24 and transmitted through the connection terminals P21 to P24 And then transmitted to the antenna 400 connected to the antenna.

The DC power transmitted through the RF cable 120 is selectively transmitted to the antenna 400 through the signal lines L21 through L24 through the power source selection unit 310 and the control signal received through the OOK communication method Signal is transmitted through the main modem 340 and converted to the RS485 standard through the RS485 driver 330 and transmitted to the RET 410 connected to the RS485 terminal unit 320. The tilt angle of the antenna 400 Can be adjusted.

The control signal received through the main modem 340 is transmitted to each of the signal lines L21 to L24 through the modem unit 260 and directly transmitted to the antenna 400 side to be transmitted to the antenna 400 via the RET To be transmitted to the mobile terminal 410.

Conversely, in the case of receiving an RF signal, the RF signal received from the antenna 400 and the status signal of the RET 410 are transmitted to the signal lines L21 through L24 through the connection terminals P21 through P24, And is transmitted to the lower interface unit 200 through the RF cable 120. [

The status signal of the RET 410 is transmitted to the common terminal COM2 through the main modem 340 and the transmitted status signal is also transmitted to the lower interface unit 200 through the RF cable 120. [

The lower interface unit 200 receives the reception signal and the status signal through the common terminal COM1 and then filters the frequency for each antenna 400 through the filters F11 to F14 to output the signal lines L11- And transmits the status signal of the RET 410 received via the main modem 240 to the AISG controller 500 through the modem unit 260 Or converts it to the RS485 method through the RS485 driver 230 and transmits the converted signal to the AISG controller 500 connected to the RS485 terminal unit 220. [

As described above, the present invention is configured to transmit the RF signal, the DC power, and the OOK communication signal through one RF cable 120, so that the installation work is easy and the cost can be reduced.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

100: base station apparatus unit 110:
120: RF cable 200: lower interface unit
300: upper interface unit 210, 310: power selection unit
220,320: RS485 terminal part 230,330: RS485 driver
240, 340: main modem 250, 350:
260, 360: modem section 400: antenna
410: RET 500: AISG controller

Claims (3)

The communication lines 110 of the base station apparatus 100 are connected to transmit the signals transmitted from the communication lines 110 through one RF cable 120 and to transmit control signals A lower interface unit (not shown) for transmitting DC power and receiving a merged signal of signals received by the antennas 400 through the RF cable 120, and for branching the signals to the communication line 110 200,
Receives a transmission signal of the base station apparatus 100 through the RF cable 120 and branches it to a transmission signal of each communication line 110 to transmit it to each of the antennas 400. In addition, Which transmits RF signals to the lower interface unit 200 through the RF cable 120 and transmits RF signals to the RETs 410 installed in the antennas 400, An interface unit 300,
And an AISG controller (500) for controlling the RET (410) by communicating with the lower interface unit (200) in an RS485 or OOK manner,
Wherein the lower interface unit comprises:
A plurality of connection terminals P11 to P14 to which the communication lines 110 are connected and signal lines L11 to L14 for transmitting RF signals and DC power to the connection terminals P11 to 14, A common terminal COM1 for transmitting a transmission signal of the plurality of communication lines L11 to L14 to the connected RF cable 120 and transmitting a reception signal to the signal lines L11 to L14, (F11 to F14) for dividing the merged signal and delivering each signal to the signal lines L11 to L14; and a filter (F11 to F14) for branching the signal line (L11 to L14) An RS485 terminal unit 220 connected to the AISG controller 500 and an RS485 driver 230 communicating with the AISG controller 500 via an RS485 communication system, The control signal of the AISG controller 500 received through the RS485 driver 230 is converted into a communication signal of the OOK method, A main modem 240 for transmitting the RF signals to the RF cable 120 through the OM1 and a control unit 250 for controlling operations of the respective units and a modem unit 260) for transmitting a signal to the mobile communication base station (200).
delete The method according to claim 1,
The upper interface unit,
A plurality of connection terminals P21 to P24 to which the antennas 400 are connected,
And transmits an RF signal, a DC power, and an OOK communication signal to the connection terminals P21 to 24 or an RF signal and an OOK communication signal of the antenna 400 and the RET 410 to the connection terminals P21 to P24 Signal lines L11 to L14,
A common terminal COM2 for transmitting the reception signals of the signal lines L11 to L14 to the connected RF cable 120 and transmitting the transmission signals to the signal lines L11 to L14,
Filters F11 to F14 provided in each of the signal lines L11 to L14 to divide the signals into which a plurality of RF signals are combined and deliver the signals to the signal lines L11 to L14,
A power selection unit 310 branched from the signal lines L11 to L14 and selectively supplying a DC current to the common terminal COM2,
An RS485 terminal unit 320 connected to the RET 410,
An RS485 driver 330 for enabling RS 485 communication with the RET 410,
A main modem 340 for converting a status signal of the RET 410 received through the RS485 driver 330 into an OOK communication signal and transmitting the communication signal to the RF cable 120 through the common terminal COM2,
A controller 350 for controlling the operations of the respective units,
And a modem unit (360) for communicating with the RET (410) in an OOK manner.

Images